工控系统中PLC安全漏洞及控制流完整性研究

doi:10.16180/j.cnki.issn1007-7820.2021.02.006

摘要/Abstract

摘要：

可编程逻辑控制器在工业控制系统中扮演着重要的角色,但近年来公开的PLC安全漏洞却呈现逐年增加的态势。针对PLC开展漏洞防御技术研究,对提高工控系统安全具有重要意义。文中基于控制流完整性,提出了一种针对PLC的控制流完整性防御机制来保护PLC免受漏洞劫持。该防御机制通过检查PLC程序中的控制转移指令,基于插桩技术插入校验指令以确保程序按照原有的控制流程图执行,以此保护PLC免受攻击者劫持。为了有效地保证PLC的实时性,引入了循环的影子堆栈。文中所提方案有效地保护了PLC免受漏洞劫持,防御机制的性能开销在平均情况下仅约为3.6%。

关键词: PLC, 漏洞, 控制流劫持, 控制流完整性, 工业控制系统, 工控安全

Abstract:

PLC plays an important role in industrial control systems. However, the security vulnerability of PLC disclosed in recent years has increased year by year. Carrying out the research on defense technology of vulnerability for PLC is of great significance for improving the security of industrial control system. Based on the control-flow integrity, this study proposes a defense mechanism using control-flow integrity for PLC to protect PLC from vulnerability hijacking. This defense mechanism protects the PLC from being hijacked by attackers through checking the control transfer instruction in the PLC program and inserting check instruction based on pile technology to ensure that the program is executed according to the original control-flow graph. In order to effectively guarantee the real-time performance of the PLC, a cyclic shadow stack is introduced. The proposed scheme effectively protects the PLC from vulnerability hijacking, and the performance overhead of the defense mechanism is only about 3.6% on average.

Key words: PLC, vulnerabilities, control-flow hijacking, control-flow integrity, industrial control system, security of industrial control system

中图分类号:

TP309

陈大伟,徐茹枝. 工控系统中PLC安全漏洞及控制流完整性研究[J]. 电子科技, 2021, 34(2): 33-37.

CHEN Dawei,XU Ruzhi. Research on Security Vulnerabilities and Control Flow Integrity of PLC in Industrial Control System[J]. Electronic Science and Technology, 2021, 34(2): 33-37.

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年份	漏洞简介	危害
2011	西门子PLC的多个协议漏洞^[6]	攻击者利用这些漏洞可以执行远程代码,达到控制流劫持的目的
2014	美国国土安全部工业控制系统网络应急响应小组公布了施耐德电气的PLC设备存在安全漏洞	漏洞允许远程未经身份验证的用户发出停止和启动命令,如果攻击者可以访问Modbus TCP端口,则攻击者无需身份验证即可停止或启动CPU,允许远程未经身份验证的用户通过Modbus下载和上传可能已修改的梯形逻辑
2015	美国国土安全部工业控制系统网络应急响应小组公布了施耐德电气Modicon M340 PLC存在一个缓冲区溢出漏洞	成功利用此漏洞可能导致攻击者访问的设备崩溃,同时缓冲区溢出可能允许远程代码执行
2016	美国国土安全部工业控制系统网络应急响应小组公布了罗克韦尔Micrologix 1100 系列的PLC存在一个缓冲区溢出漏洞	成功利用基于堆栈的缓冲区溢出漏洞可能允许攻击者远程执行受影响设备上的任意代码

PLC是否拥有CFI	平均情况下消耗的处理器周期数	最差情况下消耗的处理器周期数
否	58 325	78 046
是	60 425	82 141